CN113098437B - Adjustable wide band filter bank - Google Patents
Adjustable wide band filter bank Download PDFInfo
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- CN113098437B CN113098437B CN202110364661.2A CN202110364661A CN113098437B CN 113098437 B CN113098437 B CN 113098437B CN 202110364661 A CN202110364661 A CN 202110364661A CN 113098437 B CN113098437 B CN 113098437B
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03H—IMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
- H03H11/00—Networks using active elements
- H03H11/02—Multiple-port networks
- H03H11/04—Frequency selective two-port networks
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E40/00—Technologies for an efficient electrical power generation, transmission or distribution
- Y02E40/40—Arrangements for reducing harmonics
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Abstract
The invention discloses an adjustable wide-band filter bank, which comprises: the PCB board, set up four high-power change over switches on the PCB board: a first high-power switch SW1, a second high-power switch SW2, a third high-power switch SW3 and a fourth high-power switch SW4, seven frequency-adjustable low-pass filters connected with the high-power switches: the first adjustable frequency low-pass filter to the seventh adjustable frequency low-pass filter, and a power supply end connected with the adjustable frequency low-pass filters. The invention has the advantages of excellent out-of-band rejection performance and small in-band loss, and can accurately adjust the frequency band and the performance of the adjustable-frequency low-pass filter.
Description
Technical Field
The invention belongs to the field of wireless communication, and relates to an adjustable wide-band filter bank.
Background
In a conventional wireless communication system structure, a filter is an essential component for frequency band selection and filtering. In a transceiver, an electrically tunable filter can maintain good filtering characteristics in a wide frequency band range, but when the designed frequency band is wide and the frequency band changes greatly, the performance of the filter will begin to deteriorate at a certain frequency point, and the return loss deteriorates seriously, so that it is a very challenging subject how to increase the frequency modulation range of the filter as much as possible and compensate the performance of the loss filter.
Disclosure of Invention
The invention provides an adjustable wide-band filter bank which is excellent in out-of-band rejection performance, small in-band loss and capable of accurately adjusting the frequency band and performance of a filter.
In order to achieve the technical effects, the technical scheme of the invention is achieved in the way.
The invention provides an adjustable wide band filter bank, comprising: the PCB board, set up four high-power change over switches on the PCB board: a first high-power switch SW1, a second high-power switch SW2, a third high-power switch SW3 and a fourth high-power switch SW4, seven frequency-adjustable low-pass filters connected with the high-power switches: the first adjustable-frequency low-pass filter to the seventh adjustable-frequency low-pass filter, and a power supply end connected with the adjustable-frequency low-pass filters; a radio frequency signal enters from an antenna port ANT of a first high-power switch SW1, a first port TX1 of the first high-power switch SW1 is connected with an input end of a first frequency-adjustable low-pass filter, and an output end of the first frequency-adjustable low-pass filter is connected with a fourth port TX4 of a second high-power switch SW 2; the second port TX2 of the first high-power switch SW1 is connected with the input end of a second adjustable-frequency low-pass filter, and the output end of the second adjustable-frequency low-pass filter is connected with the third port TX3 of a second high-power switch SW 2; the third port TX3 of the first high-power switch SW1 is connected with the input end of a third adjustable-frequency low-pass filter, and the output end of the third adjustable-frequency low-pass filter is connected with the second port TX2 of a second high-power switch SW 2; a fourth port TX4 of the first high-power switch SW1 is connected with an antenna port ANT of a third high-power switch SW3, a first port TX1 of the third high-power switch SW3 is connected with an input end of a fourth adjustable-frequency low-pass filter, and an output end of the fourth adjustable-frequency low-pass filter is connected with a fourth port TX4 of a fourth high-power switch SW 4; a second port TX2 of the third high-power switch SW3 is connected with an input end of a fifth adjustable-frequency low-pass filter, and an output end of the fifth adjustable-frequency low-pass filter is connected with a third port TX3 of a fourth high-power switch SW 4; a third port TX3 of the third high-power switch SW3 is connected with an input end of a sixth adjustable-frequency low-pass filter, and an output end of the sixth adjustable-frequency low-pass filter is connected with a second port TX2 of a fourth high-power switch SW 4; a fourth port TX4 of the third high-power switch SW3 is connected with an input end of a seventh adjustable-frequency low-pass filter, and an output end of the seventh adjustable-frequency low-pass filter is connected with a first port TX1 of a fourth high-power switch SW 4; an antenna port ANT of the fourth high power switching switch SW4 is connected to the first port TX1 of the second high power switching switch SW2, and a radio frequency signal is output from the antenna port ANT of the second high power switching switch SW 2.
In the embodiment provided by the present invention, the receiving port RX of the first high power switch SW1 is connected to the receiving port RX of the fourth high power switch SW 4.
In the embodiment provided by the invention, the frequency-adjustable low-pass filter comprises a radio-frequency signal input port, a first-order parallel resonance circuit, a second-order series LC resonance circuit, a third-order parallel resonance circuit, a fourth-order series LC resonance circuit, a fifth-order parallel resonance circuit, a radio-frequency signal output port and a ground port; the radio frequency signal input port is connected with the input end of the first-order parallel resonance circuit and the input end of the second-order series LC resonance circuit, and the output end of the first-order parallel resonance circuit is connected with the grounding port; the output end of the second-order series LC resonance circuit is connected with the input ends of a third-order parallel resonance circuit and a fourth-order series LC resonance circuit, and the output end of the third-order parallel resonance circuit is connected with a ground port; and the output end of the fourth-order series LC resonance circuit is connected with the input end of the fifth-order parallel resonance circuit and the radio-frequency signal output port, and the output end of the fifth-order parallel resonance circuit is connected with the ground port.
The first-order parallel resonant circuit adopts a variable capacitance diode C1 as a grounding capacitor, the negative electrode of the variable capacitance diode C1 is grounded, and the positive electrode of the variable capacitance diode C1 is connected with a radio frequency signal input port and the input end of the second series LC resonant circuit; the second series LC resonance circuit comprises a winding inductor L1 and a capacitor C4, the inductor L1 and the capacitor C4 are connected in parallel to form a resonance loop, and the output end of the second series LC resonance circuit is connected with the input end of the third parallel resonance circuit and the input end of the fourth series LC resonance circuit; the third parallel resonant circuit adopts a variable capacitance diode C2 as a grounding capacitor, the negative electrode of the variable capacitance diode C2 is grounded, and the positive electrode of the third parallel resonant circuit is connected with the output end of the second series LC parallel resonant circuit and the input end of the fourth series LC resonant circuit; the fourth series LC resonance circuit comprises a winding inductor L2 and a capacitor C5, the inductor L2 and the capacitor C5 are connected in parallel to form a resonance loop, and the output end of the fourth series LC resonance circuit is connected with the input port of the fifth parallel resonance circuit and the output port of the radio frequency signal; the fifth parallel resonant circuit adopts a variable capacitance diode C3 as a grounding capacitor, the negative electrode of the variable capacitance diode C3 is grounded, and the positive electrode of the variable capacitance diode C3 is connected with the output end of the fourth series LC resonant circuit and the radio frequency signal output port.
In an embodiment provided by the invention, the supply terminal comprises three tunable voltages: tunable voltage Vcc1, tunable voltage Vcc2, tunable voltage Vcc 3; the tunable voltage Vcc1 is connected with each first-order parallel resonant circuit; the tunable voltage Vcc2 is connected to each third order parallel resonant circuit; the tunable voltage Vcc3 is connected to each fifth order parallel resonant circuit.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.
Fig. 1 is a block diagram of an adjustable frequency broadband filter according to an embodiment of the present invention.
Fig. 2 is a schematic diagram of an adjustable-frequency low-passband filter according to an embodiment of the invention.
Detailed Description
The present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the invention by referring to the description text.
It will be understood that terms such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.
The terms "first" and "second," and the like, in the description and in the claims of embodiments of the present invention are used for distinguishing between different objects and not for describing a particular order of the objects.
The technical scheme of the invention is described in detail in the following with reference to the accompanying drawings.
As shown in fig. 1, the present invention provides a tunable wideband filter bank, comprising: the PCB board, set up four high-power change over switches on the PCB board: a first high-power switch SW1, a second high-power switch SW2, a third high-power switch SW3, a fourth high-power switch SW4, seven tunable low-pass filters Filter connected with the high-power switches: the Filter comprises a first adjustable frequency low-pass Filter1 to a seventh adjustable frequency low-pass Filter7, and a power supply end Vtune connected with the adjustable frequency low-pass filters;
furthermore, the high-power switch and the frequency-adjustable low-pass filter are fixed on the PCB through soldering.
A radio frequency signal enters from an antenna port ANT of a first high-power switch SW1, a first port TX1 of the first high-power switch SW1 is connected with an input end of a first frequency-adjustable low-pass filter, and an output end of the first frequency-adjustable low-pass filter is connected with a fourth port TX4 of a second high-power switch SW 2;
the second port TX2 of the first high-power switch SW1 is connected with the input end of a second adjustable-frequency low-pass filter, and the output end of the second adjustable-frequency low-pass filter is connected with the third port TX3 of a second high-power switch SW 2;
the third port TX3 of the first high-power switch SW1 is connected with the input end of a third adjustable-frequency low-pass filter, and the output end of the third adjustable-frequency low-pass filter is connected with the second port TX2 of a second high-power switch SW 2;
a fourth port TX4 of the first high-power switch SW1 is connected with an antenna port ANT of a third high-power switch SW3, a first port TX1 of the third high-power switch SW3 is connected with an input end of a fourth adjustable-frequency low-pass filter, and an output end of the fourth adjustable-frequency low-pass filter is connected with a fourth port TX4 of a fourth high-power switch SW 4;
a second port TX2 of the third high-power switch SW3 is connected with an input end of a fifth adjustable-frequency low-pass filter, and an output end of the fifth adjustable-frequency low-pass filter is connected with a third port TX3 of a fourth high-power switch SW 4;
a third port TX3 of the third high-power switch SW3 is connected with an input end of a sixth adjustable-frequency low-pass filter, and an output end of the sixth adjustable-frequency low-pass filter is connected with a second port TX2 of a fourth high-power switch SW 4;
a fourth port TX4 of the third high-power switch SW3 is connected with an input end of a seventh adjustable-frequency low-pass filter, and an output end of the seventh adjustable-frequency low-pass filter is connected with a first port TX1 of a fourth high-power switch SW 4;
an antenna port ANT of the fourth high power switching switch SW4 is connected to the first port TX1 of the second high power switching switch SW2, and a radio frequency signal is output from the antenna port ANT of the second high power switching switch SW 2.
It can be understood that, in the embodiment provided by the present invention, seven adjustable frequency low-pass filters are all connected to the high-power switch, and then the on-off of different adjustable frequency low-pass filters is controlled by external logic, so that only one adjustable frequency low-pass filter can be ensured to work normally in the same time period.
It should be noted that, in the technical solution of the present invention, not only four high-power switches and seven adjustable frequency low-pass filters are limited, but also different numbers of high-power switches and adjustable frequency low-pass filters can be used according to different modifications.
Optionally, in an embodiment provided by the present invention, the receiving port RX of the first high-power switch SW1 is connected to the receiving port RX of the fourth high-power switch SW 4.
That is, the whole module has seven frequency-adjustable low-pass filters for link transmission, and one path of reception for the receiving path of the whole link, and in order to reduce the loss of the received signal, the frequency-adjustable low-pass filter is not added here, and the receiving port RX of the first high-power switch is directly connected with the receiving port RX of the second high-power switch, and is used as the receiving channel of the frequency-adjustable low-pass filter module.
It can be understood that in the embodiment provided by the present invention, the whole tunable wideband frequency-tunable low-pass filter bank has transmitting and receiving functions, and has a total of four ports, i.e., a radio frequency input port RFin, a radio frequency output port RFout, a ground port GND, and a power supply port Vtune.
As shown in fig. 2, the topology structure of the tunable low-pass filter includes 2 winding inductors, 2 capacitors, and 3 varactors to form an LC tunable low-pass filter, the inductor L1 is connected in parallel with the capacitor C4, and the inductor L2 is connected in parallel with the capacitor C5 to form a resonant circuit, and the varactors C1, C2, and C3 are grounded to improve the out-of-band rejection performance of the tunable low-pass filter.
As can be seen from fig. 2, the tunable low-pass filter includes a radiofrequency signal input port RFin, a first-order parallel resonant circuit, a second-order series LC resonant circuit, a third-order parallel resonant circuit, a fourth-order series LC resonant circuit, a fifth-order parallel resonant circuit, a radiofrequency signal output port RFout, and a ground port GND;
the radio frequency signal input port is connected with the input end of the first-order parallel resonance circuit and the input end of the second-order series LC resonance circuit, and the output end of the first-order parallel resonance circuit is connected with the grounding port;
the output end of the second-order series LC resonance circuit is connected with the input ends of a third-order parallel resonance circuit and a fourth-order series LC resonance circuit, and the output end of the third-order parallel resonance circuit is connected with a ground port;
and the output end of the fourth-order series LC resonance circuit is connected with the input end of the fifth-order parallel resonance circuit and the radio-frequency signal output port, and the output end of the fifth-order parallel resonance circuit is connected with the ground port.
Further, in the embodiment provided by the present invention, the first-order parallel resonant circuit uses a varactor C1 as a ground capacitor, a cathode of the varactor C1 is grounded, and an anode of the varactor C1 is connected to the rf signal input port and the input end of the second series LC resonant circuit; the second series LC resonance circuit comprises a winding inductor L1 and a capacitor C4, the inductor L1 and the capacitor C4 are connected in parallel to form a resonance loop, and the output end of the second series LC resonance circuit is connected with the input end of the third parallel resonance circuit and the input end of the fourth series LC resonance circuit; the third parallel resonant circuit adopts a variable capacitance diode C2 as a grounding capacitor, the negative electrode of the variable capacitance diode C2 is grounded, and the positive electrode of the third parallel resonant circuit is connected with the output end of the second series LC parallel resonant circuit and the input end of the fourth series LC resonant circuit; the fourth series LC resonance circuit comprises a winding inductor L2 and a capacitor C5, the inductor L2 and the capacitor C5 are connected in parallel to form a resonance loop, and the output end of the fourth series LC resonance circuit is connected with the input port of the fifth parallel resonance circuit and the output port of the radio frequency signal; the fifth parallel resonant circuit adopts a variable capacitance diode C3 as a grounding capacitor, the negative electrode of the variable capacitance diode C3 is grounded, and the positive electrode of the variable capacitance diode C3 is connected with the output end of the fourth series LC resonant circuit and the radio frequency signal output port. Therefore, the frequency band adjustable characteristic of the adjustable-frequency low-pass filter is realized, the out-of-band rejection performance of the adjustable-frequency low-pass filter is improved, and the optimal performance of the adjustable-frequency low-pass filter in a useful radio frequency signal frequency band range is ensured.
Further, in an embodiment provided by the present invention, the power supply terminal includes three tunable voltages: tunable voltage Vcc1, tunable voltage Vcc2, tunable voltage Vcc 3; the tunable voltage Vcc1 is connected with each first-order parallel resonant circuit; the tunable voltage Vcc2 is connected to each third order parallel resonant circuit; the tunable voltage Vcc3 is connected to each fifth order parallel resonant circuit. The frequency band characteristic of the frequency-adjustable low-pass filter is adjusted by adjusting the capacitance value of the variable capacitance diode through the tuning voltage Vcc.
While embodiments of the invention have been disclosed above, it is not intended that they be limited to the applications set forth in the specification and examples. It can be applied to all kinds of fields suitable for the present invention. Additional modifications will readily occur to those skilled in the art. It is therefore intended that the invention not be limited to the exact details and illustrations described and illustrated herein, but fall within the scope of the appended claims and equivalents thereof.
Claims (3)
1. A tunable wideband filter bank, comprising: the PCB board, set up four high-power change over switches on the PCB board: a first high-power switch SW1, a second high-power switch SW2, a third high-power switch SW3 and a fourth high-power switch SW4, seven frequency-adjustable low-pass filters connected with the high-power switches: the first adjustable-frequency low-pass filter to the seventh adjustable-frequency low-pass filter, and a power supply end connected with the adjustable-frequency low-pass filters;
a radio frequency signal enters from an antenna port ANT of a first high-power switch SW1, a first port TX1 of the first high-power switch SW1 is connected with an input end of a first frequency-adjustable low-pass filter, and an output end of the first frequency-adjustable low-pass filter is connected with a fourth port TX4 of a second high-power switch SW 2;
the second port TX2 of the first high-power switch SW1 is connected with the input end of a second adjustable-frequency low-pass filter, and the output end of the second adjustable-frequency low-pass filter is connected with the third port TX3 of a second high-power switch SW 2;
the third port TX3 of the first high-power switch SW1 is connected with the input end of a third adjustable-frequency low-pass filter, and the output end of the third adjustable-frequency low-pass filter is connected with the second port TX2 of a second high-power switch SW 2;
a fourth port TX4 of the first high-power switch SW1 is connected with an antenna port ANT of a third high-power switch SW3, a first port TX1 of the third high-power switch SW3 is connected with an input end of a fourth adjustable-frequency low-pass filter, and an output end of the fourth adjustable-frequency low-pass filter is connected with a fourth port TX4 of a fourth high-power switch SW 4;
a second port TX2 of the third high-power switch SW3 is connected with an input end of a fifth adjustable-frequency low-pass filter, and an output end of the fifth adjustable-frequency low-pass filter is connected with a third port TX3 of a fourth high-power switch SW 4;
a third port TX3 of the third high-power switch SW3 is connected with an input end of a sixth adjustable-frequency low-pass filter, and an output end of the sixth adjustable-frequency low-pass filter is connected with a second port TX2 of a fourth high-power switch SW 4;
a fourth port TX4 of the third high-power switch SW3 is connected with an input end of a seventh adjustable-frequency low-pass filter, and an output end of the seventh adjustable-frequency low-pass filter is connected with a first port TX1 of a fourth high-power switch SW 4;
an antenna port ANT of the fourth high-power switch SW4 is connected with a first port TX1 of a second high-power switch SW2, and a radio frequency signal is output from the antenna port ANT of the second high-power switch SW 2;
the frequency-adjustable low-pass filter comprises a radio-frequency signal input port, a first-order parallel resonance circuit, a second-order series LC resonance circuit, a third-order parallel resonance circuit, a fourth-order series LC resonance circuit, a fifth-order parallel resonance circuit, a radio-frequency signal output port and a ground port;
the radio frequency signal input port is connected with the input end of the first-order parallel resonance circuit and the input end of the second-order series LC resonance circuit, and the output end of the first-order parallel resonance circuit is connected with the grounding port;
the output end of the second-order series LC resonance circuit is connected with the input ends of a third-order parallel resonance circuit and a fourth-order series LC resonance circuit, and the output end of the third-order parallel resonance circuit is connected with a ground port;
the output end of the fourth-order series LC resonance circuit is connected with the input end of a fifth-order parallel resonance circuit and a radio frequency signal output port, and the output end of the fifth-order parallel resonance circuit is connected with a ground port;
the first-order parallel resonant circuit adopts a variable capacitance diode C1 as a grounding capacitor, the negative electrode of the variable capacitance diode C1 is grounded, and the positive electrode of the variable capacitance diode C1 is connected with a radio frequency signal input port and the input end of the second series LC resonant circuit;
the second series LC resonance circuit comprises a winding inductor L1 and a capacitor C4, the inductor L1 and the capacitor C4 are connected in parallel to form a resonance loop, and the output end of the second series LC resonance circuit is connected with the input end of the third parallel resonance circuit and the input end of the fourth series LC resonance circuit;
the third parallel resonant circuit adopts a variable capacitance diode C2 as a grounding capacitor, the negative electrode of the variable capacitance diode C2 is grounded, and the positive electrode of the third parallel resonant circuit is connected with the output end of the second series LC parallel resonant circuit and the input end of the fourth series LC resonant circuit;
the fourth series LC resonance circuit comprises a winding inductor L2 and a capacitor C5, the inductor L2 and the capacitor C5 are connected in parallel to form a resonance loop, and the output end of the fourth series LC resonance circuit is connected with the input port of the fifth parallel resonance circuit and the output port of the radio frequency signal;
the fifth parallel resonant circuit adopts a variable capacitance diode C3 as a grounding capacitor, the negative electrode of the variable capacitance diode C3 is grounded, and the positive electrode of the variable capacitance diode C3 is connected with the output end of the fourth series LC resonant circuit and the radio frequency signal output port.
2. The tunable wide band filter bank of claim 1, wherein said receive port RX of said first high power switch SW1 is connected to said receive port RX of said fourth high power switch SW 4.
3. The tunable wide-band filter bank according to claim 1, wherein the supply terminal comprises three tunable voltages: tunable voltage Vcc1, tunable voltage Vcc2, tunable voltage Vcc 3;
the tunable voltage Vcc1 is connected with each first-order parallel resonant circuit;
the tunable voltage Vcc2 is connected to each third order parallel resonant circuit;
the tunable voltage Vcc3 is connected to each fifth order parallel resonant circuit.
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Address after: Building 12, Hard Technology Enterprise Community, No. 3000 Biyuan Second Road, High tech Zone, Xi'an City, Shaanxi Province, 710065 Patentee after: Borui Jixin (Xi'an) Electronic Technology Co.,Ltd. Address before: 22nd floor, East Building, block B, Tengfei Kehui City, 88 Tiangu 7th Road, Yuhua Street office, high tech Zone, Xi'an, Shaanxi 710000 Patentee before: XI'AN BORUI JIXIN ELECTRONIC TECHNOLOGY Co.,Ltd. |